DE2219090C3 - Circuit arrangement for telecommunications, in particular telephone systems, in which data is entered from subscriber stations into a memory of a computer - Google Patents

Description

The invention relates to a circuit arrangement for telecommunications, in particular telephone systems, in which from subscriber stations from data into a memory of a computer via a computer-controlled Data transfer can be entered.

A computer is often already available in such systems, for example to control the structure of telephone connections or the like, which is also used for other purposes. So can the computer z. B. keep an inventory file or a child file, or even with flexible working hours record the time of when the respective person arrived at the workplace or him has left again. These data are transmitted in a known manner with the help of punch cards, plastic cards Keying in etc. after selecting a code number entered into the computer and stored there in a data memory noted.

Since the computer is not like a subscriber to an Ar terminal of telephones or telex typing devices There are one or more between the computer and the switchboard Data transfers inserted that make the necessary circuit and timing adjustments. In order to keep the number of connection lines between the computer and the exchange low, there are a few Systems designed so that the computer its commands to the data transmission and similar peripheral devices with a temporal security that However, execution of these commands is not directly monitored. The computer works much faster than the peripheral devices, so that he can operate a variety of such devices at the same time when he is himself not busy with every single device for too long. The computer is therefore only briefly connected to the peripheral devices connected. During this time he transmits his orders to them without carrying them out to be seen. In a system of the type mentioned above, the computer also ensures that only one Data transfer from the total number for the next incoming occupancy from a calling one Participant is provided. In this way, the data transmissions can freely change the switching states (available), occupied, provided, absent or blocked.

Circuit arrangements are also known in which the switching state of subscriber lines, Transmissions, etc. is detected by scanning (scanning).

The object of the invention is to enable the computer in systems of the type mentioned, which To control the execution of the commands issued by it in the peripheral devices without loss of time, so that data traffic via devices that have not assumed the required switching status is prevented. In addition, the occurrence of a failure in a peripheral device is as quick as possible and specify the wrong location as precisely as possible.

This is achieved according to the invention in that

a known scanning device (scanner) to the computer is assigned to the computer with the data transfers in a cyclic order one after the other that connects the computer for condition monitoring a known state memory is assigned to the data transfers that simultaneously with the output of a command to change the switching status of one of the file transmissions Change as carried out is noted in the state memory that the noted states in by the Scanning device specified rhythm continuously with the actual states of the data transmissions be compared that if the two related states do not match, the relevant Data transmission is marked as faulty and unassignable in the state memory, and that thereupon an error alarm is given and / or all necessary information about the faulty data transmission can be printed out.

The fact that the switching status of each data transmission is recorded in the status memory of the computer is, the computer knows the target state of these devices. In the event of deviations from the actual state that occurs when scanning of data transfers is detected, it is not only obvious in which device there is a fault has occurred, but also which switching process was not carried out, at which point on the device so the fault is to be looked for.

According to the invention, the computer does not wait for its commands from the switching means of the data transmissions be executed, but it will be used for new tasks immediately after the instruction has been issued provided. This does not delay the scan cycle, and so does the other peripheral devices be served as quickly as possible. Not until the next sampling cycle, which is after a small fraction of a Second follows, it is determined whether the expected effect has occurred. This way it becomes without Loss of time checks whether the slower switching means for data transmission have worked properly.

According to a further embodiment of the invention, the state determined during the first scan is not evaluated, but only that of the second scan. This has the advantage that with data transfers slowly working switching means the change of state is definitely complete when the Scanning result is evaluated.

Another embodiment of the invention provides that commands are combined into command words that have a certain length. In this way the output of the commands is prepared so that the maximum the number of commands for a call that can be transmitted over the multiple lines is available at the same time and is immediately applied to the multiple lines when requested.

Further features and advantages of the invention will become apparent from the following description of a in the drawing illustrated embodiment of the circuit arrangement according to the invention.

A switch V, for example, a telephone exchange is connected to a computer R via a number of data transfers Ui to Un, and a Anschalter A. Different characters are exchanged between the exchange V and the data transmissions via the wires / 1 to fn , such as receipts, signal tones, hanging characters, key press signals, etc.

In the data transmission Ui , a contact ArI is shown, which is drawn here to represent several sampling points. The relay B 1 also shown receives one of the commands issued by the computer R. It is switched on, for example, with a pulse when the data transmission U \ has been designated by a chain circuit contained in the computer R as the next transmission to be occupied. Another impulse throws this relay off again.

The same contacts Arn and a relay Bn are also built into the data transmission Un and in all data transmissions in between

The switch A is connected to the computer R with a number of address lines w and with the multiple lines ν . The address is transmitted via the address lines w , that is to say, for example, the information about which data transmission U 1 to Un is to be connected to the computer R via the multiple lines ν, whether a code receiver is to be connected, whether there is a subscriber authorization, the subscriber number, etc.

The computer R has a data memory of no further interest here, in which the data entered by the subscriber are to be stored and collected. A status memory Z contains the target status information for all data transmissions U \ to Un. A scanning device 5 gives instructions to the switch A as to which of the data transmissions Ui to Un are to be scanned for their switching state. A command memory B serves as a buffer for the commands to be output for the data transmissions U \ to LIn. In addition, the computer also contains a chain circuit that determines the order of the commands to be issued, and a chain circuit that specifies which of the data transmissions U I to Un is to be occupied next by a calling subscriber.

As soon as a subscriber who is connected to the exchange V wishes to enter any data into the computer R , he dials a code number that corresponds to the type of data. After an authorization has been established, the call arrives at one of the data transmissions U 1 to Un via one of the wires f \ to fn. The data information is then forwarded to the computer R in a way not shown further and entered there in the data memory.

Which of the data transmissions Ui to Un the subscriber arrives at is predetermined by the chain connection of the computer R. The selected data transmission, for example U 1, is marked accordingly by energizing the relay B 1. It does this in the following way.

For this example it is assumed that between the computer R and the connector A 16 multiple lines v, between the connector A and each of the data transmissions Ui to Un run four wires di to dn and four wires e 1 to en .

When the system is switched on, all data transmissions U 1 to Un are in the idle position. The scanning device S starts up and transmits the message via the address lines w to the connection switch A that four wires d 1 of the 16 wires of the multiple lines ν are to be connected to the four contacts AI of the data transmission Ui . Each further four wires are connected to the data transmissions U2 to U4, not shown here. In this way, these four data transmissions form a transmission group which is scanned at the same time and the scanning result of which is transmitted to the computer R at the same time.

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connected to the computer and so on until the last data transmission L / n is queried.

The result of these scans is initially the same for all transmissions and indicates that they are all free and present. Since no other target state is noted in the state memory Z, there is no evaluable deviation. If one of the data transmissions is not present, this status is also reported to the computer R. However, this fact is written into the status memory so that no commands are transmitted to the output for the relevant transmission.

After a complete sampling cycle, it is now the task of the computer R to determine one of the data transmissions via which the first incoming call to the computer R is to be connected through. The address of the transmission predetermined by the daisy chain, e.g. B. i / 1, is written into the instruction memory B including the type of instruction. At the same time, it is noted in the status memory Z that this data transmission has been pre-assigned by the computer.

According to the assumption that the division lines ν of 16 wires, and in that for each data transmission U1 to Un four control wires e 1 lead to s, the total number of data transmissions is again of four to a transmission group summarized All instructions in the instruction memory B to to be transmitted to each of the transmission groups form a command word, regardless of whether none or many commands are provided for the respective group.

Since, according to the assumption, there is only a command for data transmission U 1, only the first command word is available for transmission. This is now, provided with an address, transmitted to the connector A via the multiple lines ν. Because the computer R is only connected to the connector A for a very short time, but the circuit elements of the data transmission work much more slowly, there are one or more buffers in the connector A that accept the commands and keep them connected to the wires e 1 until the relay B 1 has responded safely In the meantime, the computer R is busy with the next tasks.

Controlled by the scanning device S, all data transmissions i / l to Un are again scanned, their switching status is transmitted to the computer R and compared with the memory content of the status memory Z. It is possible that the relay B 1 has not yet fully responded and therefore the contacts k 1 are not yet fully actuated. Since the memory R knows that the data transmission U 1 has just received a command, its sampling value is also not used, but only the next, the third sampling is awaited

After this second scan, the computer controlled by the chain circuit already mentioned, it determines whether the next command word contains a command if this is not the case, then the next one, etc. Command word is examined until one full cycle derailleur has taken place. If no waiting command could be found, after Expiry of a measured waiting time the next, third scan cycle begin «. But said commands in one or more command words are present, the first one specified by the chain connection is used Command word, as already described, to the appropriate Transmission group issued. In this way, only one is generated between two sampling cycles Transfer command word, the next command words must wait accordingly until it is their turn.

In addition to the already described switching states »free and available«, »provided by the computer«, »Not available«, the switching states »occupied« and »blocked« are also possible.

The switching state "occupied" is assumed when a subscriber has called and is connected to the computer R by the exchange V. Because the switching state "occupied by the computer" has changed to the "occupied" state, the computer R ensures that the next data transmission, for example i / 2, is pre-assigned by the computer in the manner already described.

As already described, each of the data transmissions Ui to Un has four outputs from the sampling points k 1, which can be combined as desired. This results in 16 possible operating states during the scanning process, ie the contact combination can change from each state to 15 others. These changes of state can be logically meaningful or nonsensical. The sensible ones lead to the interpretation when comparing the target state, as defined in the state memory Z, with the actual state, as determined during the scanning. If it turns out that the two states still do not match during the second scan cycle, the command has either not been accepted by the data transfer, or the command has been accepted but has not been carried out, or the command has been accepted executed but the data transfer has returned to its original state or into a different switching state. This fact is to be seen as a mistake.

Before the faulty data transmission, e.g. i / l. is signaled and printed out, and is also blocked in the state memory Zund in the chain circuit, the computer R looks in the command memory B to see whether the command has already been issued for the data transfer or whether it is still waiting in the command memory B with the transfer of each command to the Command memory B is namely at the same time entered in the state memory Z the command as already executed, so that the comparison of the actual state with the target state can be made. If the command is still in the command memory B, a comparison is made again after two further scanning cycles until the command is stored.

Should the command still be in the command memory after a certain number of queries. so is an alarm and a printout of the error are also provided here.

As described above, a transfer of a command to the command memory B simultaneously leads to a change in the occupancy status, ie the SoB status, the corresponding data transfer in the status memory Z. However, it is also possible to leave the status memory Z unchanged and only when the Command from the command memory B set a corresponding memory point in the state memory Zzu. In this case, the query to the command memory B entSlit whether the command has already been issued to the corresponding data transmission or not

If a nonsensical state arises when the data transmissions Ui to Un are scanned, special error routine tests are started.

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which also lead to an error expression and a blocking of the transmission.

In this way , errors that indicate wire breaks, line interruptions or other defects in components are identified with an indication of the location of the error and the faulty step and the maintenance personnel are informed.

As soon as the defective assembly is removed from the frame during maintenance, the relevant storage point in the status memory Z takes on the switching status "not available", which changes to the status "free and available" after a new data transfer has been inserted.

1 sheet of drawings

9WB10 / 2J9

Claims (6)

Patent claims: 1. Circuit arrangement for telecommunications, in particular telephone systems, in which data can be entered from subscriber stations into a memory of a computer via a computer-controlled data transmission, characterized in that the computer (R) is assigned a known scanning device (scanner S) 1 ο which connects the computer (R) to the data transmissions (L / 1 to Un) one after the other in a cyclic sequence that the computer (R) is assigned a known status memory (Z) for monitoring the status of the data transmissions (U 1 to Un) that simultaneously with the output of a defect to change the switching state of one of the data transmissions (UX) this change is noted as executed in the state memory (Z) , that the noted states in the rhythm specified by the scanning device (S) continuously with the actual states of the Data transmissions (U 1 to Un) are compared that if the two belonging together do not match en states, the relevant data transmission (UX) is marked as faulty and unassignable in the status memory (Z) , and that thereupon an error alarm is given and / or all necessary information about the faulty data transmission (U 1) is printed out. 2. Circuit arrangement according to claim!. Characterized in that a switch (A) is inserted between the data transmissions (U 1 to Un) and the computer (R). controlled by the scanning device (S) , the multiple lines (v ) running between the computer (R) and the connection switch (A) with the switching means (R 1 to Rn) receiving the command to change the switching state and / or with the test points to be scanned ( k 1 to kn) of the data transmissions (UX to Un) at the specified time via connection lines (e 1 to en, d X to dn) . 3. Circuit arrangement according to claim 2, characterized in that during a scanning process all test points (k X to kn) of the data transmissions (U 1 to Un) are scanned, that after a subsequent comparison in an instruction memory (B) of the computer Walle to the data transmissions (UX to Un) to be sent out change commands are stored that command words of such a length (number of bits) are formed in these memories as wires (16) are present in the multiple lines (v) and that the test points (k 1 to kn) a single command word is output to the data transmissions (U 1 ... U 4) specified in an address transmitted via address lines (w). 4. Circuit arrangement according to claim 3, characterized in that each computer has a chain circuit is assigned, which determines the order of the command words to be output. 5. Circuit arrangement according to claim 1, characterized in that the computer is assigned a chain circuit which determines the sequence of the data transmissions (U 1 to Un) for the occupancy of a calling subscriber. 6. Circuit arrangement according to claim 1, characterized in that only when the switching state of the data transmission (UX) does not match during the second scanning with the state noted in the state memory (Z) these data transmissions (UX) are regarded as faulty